Hydraulic damper

ABSTRACT

A compensating damper comprises opposed working end faces, a hermetically sealed chamber between the working end faces, and a set of plates in the chamber with a film of viscous fluid between each pair of adjacent plates. The damper has at least two different film thickness zones across the set of plates, each of the different film thickness zones providing a different resistance response when acted upon by an outside force exerted on at least one of the opposed working end faces. Multiple internal guide pins may extend axially from the opposed working end faces for engaging the plate stack partially from each of said working end faces to increase the stroke while providing for a compact damper. The plates may have a conical configuration to providing dampening in different plans.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. application Ser. No.14/653,493, filed Jun. 18, 2015, which is a National Phase Entry of PCTapplication No. PCT/CA2013/001081, filed Dec. 20, 2013, which claimspriority on US provisional applications Nos. 61/740,041 filed on Dec.20, 2012, and 61/845,544 filed on Jul. 12, 2013, the content of allthese applications being incorporated herein by reference.

TECHNICAL FIELD

The application relates generally to force limiting devices, such asdampers or hydraulic cushions, suited for absorbing or dissipatingenergy through the flow of a fluid.

BACKGROUND ART

Energy absorbing devices are used in various applications. Over theyears, various types of such devices have been developed. However, ithas always been challenging to design a device that has the ability ofefficiently dissipating high frequency, high force and low amplitudeoscillations of short duration. Also, commercially available energyabsorbing devices have a relatively limited range of applicability.

There thus remains room for improvements.

SUMMARY

In accordance with a first aspect of the present application, there isprovided a compensating damper comprising opposed working end faces, ahermetically sealed chamber between the working end faces, a set ofplates in the chamber with a film of viscous fluid between each pair ofadjacent plates, characterized in that there being at least twodifferent film thickness zones across the set of plates, each of thedifferent film thickness zones providing a different resistance responsewhen acted upon by an outside force exerted on at least one of saidopposed working end faces.

In accordance with a second aspect, there is provided a compensatingdamper comprising a set of plates distributed along an axis and receivedin a chamber containing a working fluid, each plate having a workingface generally normal to said axis, said working face having aneffective surface area, each plate at rest being axially spaced from anadjacent plate by an inter-plate gap filled by the working fluid, eachindividual plate forming a piston for working on the volume of theworking fluid between it and the next plate, the plates being axiallymovable towards and away from each other, at least a portion of theworking fluid being squeezed out from between the plates in response toan axial compressive load transferred to the set of plates, wherein thechamber has opposed end working faces generally normal to the axis, theset of plates being disposed between said working end faces, andmultiple internal guide pins extending axially from the opposed workingend faces and engaging the plate stack partially from each of saidworking end faces.

In accordance with a third aspect, there is provided a compensatingdamper comprising an arrangement of plates contained in a chamber filledwith a viscous fluid, the arrangement of plates comprising an array ofconical plates nested into one another with a film of viscous fluidbetween adjacent plates, the conical shape of the plates providingdampening in more than one geometric plane at once.

In accordance with a still further aspect, there is provided acompensating damper energy dissipating link, comprising a sealedcanister holding a stack of fluid filled plates and with an externaltubular structural wall providing sufficient structural strength toallow the canister to act as a solid mounting link, a pair of workingfaces between which the stack of fluid filled plates is held, a joint ata first end of the canister to permit mounting of the link and a rodtype arrangement projecting from a second end of the canister, a weakpoint between the rod type arrangement and the second end to cause astress concentration point to fracture when a force exceeding the normaloperation is encountered, thereby allowing the rod to be run into thecanister and provide access to the dampening action.

Further details of these and other aspects of the present invention willbe apparent from the detailed description and figures included below.

DESCRIPTION OF THE DRAWINGS

Reference is now made to the accompanying figures, in which:

FIG. 1 is a schematic cross-section view of a single-acting variant of ahydraulic damper comprising a set of damping plates;

FIG. 2 is a schematic exploded view of the damper shown in FIG. 1;

FIG. 3a is a schematic perspective view of a first type of plate thatmay form part of the set of damping plates of the damper shown in FIG.1;

FIGS. 3b and 3c are respectively schematic oblique and side viewsillustrating a second type of plates that may form part of the dampingplates of the damper shown in FIG. 1;

FIG. 4 is a schematic cross-section view of a double-acting variant of ahydraulic damper in accordance with another embodiment of the presentinvention;

FIG. 5 is a schematic cross-section view of an internally pre-loadeddouble-acting variant of a hydraulic damper in accordance with a furtherembodiment of the present invention;

FIG. 6 is a schematic exploded perspective view of a torsional dampermounting arrangement in accordance with a still further embodiment ofthe present invention;

FIG. 7 is a schematic cross-section view of the torsional dampermounting arrangement shown in FIG. 6;

FIG. 8 is a schematic cross-section view illustrating a hydrauliccylinder end stop embodiment of the present invention;

FIG. 9 is a schematic air cylinder end stop embodiment of the presentinvention;

FIG. 10 is a dead blow hammer head embodiment of the present invention;

FIG. 11 is a table and chair anti-wobble embodiment of the presentinvention;

FIG. 12 shows a protective device having a plurality of shock absorbingmembers each including a stack of free floating piston platesindividually acting on a film of fluid filling each gap between adjacentplates;

FIGS. 13a and 13b show an embodiment of a compensating damperincorporated into the recoil pad of shoulder fired guns;

FIGS. 14a, b and c show the adaptation of an embodiment of acompensating damper in machine vibration isolation bases;

FIGS. 15a, b and c show the integration of an embodiment of acompensating damper into energy dissipating mounting links of a militaryvehicle for reducing the force which occupants of the military vehiclemay be subjected to during the encounter with Improvised ExplosiveDevices (LEDs), explosions or land mines;

FIGS. 16a to 16e illustrate a vibration isolation base to protectsensitive electronic equipment;

FIGS. 17a to 17e illustrate a further embodiment of a force limitingdevice including multiple internal guiding pins; and

FIGS. 18a to 18d illustrate a mounting system for mounting a recoil padhaving a compensating damper such as the one shown in FIG. 13 to ashoulder fired firearm.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 illustrates a force limiting device which may be provided in theform of a hydraulic damper 10 comprising a housing 12 defining ahermetic chamber 14 having an axis 16. The chamber 14 contains a workingfluid 18 and a stack or set of parallel plates 20 disposed generallynormal to the axis 16. The plates 20 are “floatingly” received in thechamber 14 and are movable relative to each other along axis 16. Atrest, each plate 20 is separated from the adjacent plates 20 by aninter-plate gap 22 occupied by the working fluid 18. The capillaryaction of the fluid 18 contributes to maintain the plates 20 axiallyspaced-apart from each other.

As shown in FIGS. 1 and 2, the housing 12 may comprise first and secondaxially opposed counter-acting members 24 and 26 joined by anelastomeric boot 28. The first and second members 24 and 26 cooperatetogether with the elastomeric boot 28 to define the hermetic chamber 14.The elastomeric boot 28 allows the first member 24 to move towards andaway from the second member 26 under the action of external forces F.Alternatively, the first member 24 could be slidably received in atube/cylinder axially extending from the second member 26 or vice versa.The first and second members 24 and 26 are provided with respectivemounting structures for allowing mounting thereof between two parts of astructure requiring damping. For instance, damper 10 could be interposedbetween the frame and the engine of motorized equipment, or integratedinto aerospace components to dampen vibrations. In the illustratedexample, the first member 24 has a central threaded hole 30, whereas thesecond member 26 has a central threaded stud portion 32. It isunderstood that any other suitable attaching/mounting structure could beprovided.

As shown in FIGS. 1 and 2, the first member 24 may be provided on aninwardly facing surface thereof with an axially extending central rod orshaft 34. The distal end portion of the shaft 34 is adapted to beslidably received in a corresponding central guiding recess 36 definedin the inwardly facing surface of the second member 26. The engagementof the shaft 34 in recess 36 ensures proper axial alignment of the firstand second end members 24 and 26 at all times. In other words the shaftand recess arrangement axially guides the relative movement between thefirst and second members 24 and 26.

As shown in FIG. 2, each plate 20 may be provided with a central hole 38for allowing the plates 20 to be slidably/loosely mounted on the shaft34 for relative axial movement with respect thereto. The plates 20 areprevented from axially sliding off of the shaft 34 by virtue of theengagement of the distal end portion of the shaft 34 in the centralguiding recess 36; the inner face of the second member 26 acting as astopper for the plates 20. It is understood that other suitablemechanisms could be used to prevent the plates 20 from sliding off theshaft 34. According to an alternate embodiment, the plates 20 could beloosely confined/guided in a rigid tube (not shown) instead of beingfitted on a central shaft. The two counter-acting members 24 and 26could be prevented from escaping each other axially by the following:The shaft 34 could be hollow and have a slot cut into its length. Intothe hollow shaft, and co-axially to it would enter a pin protruding fromthe inner face of the second member 26, and be prevented from coming outof engagement from shaft 34 by a roll pin installed through the end ofthe pin protruding from member 26, and sliding in the slot.

As shown in FIGS. 2, 3 a, 3 b and 3 c, the plates 20 may have a circularshape. The outer circumference of the plates 20 generally corresponds tothat of the opposed inner faces of the first and second members 24 and26. The plates 20 may be made out of metallic material. However, it isunderstood that other suitable materials could be used as well. As shownin FIGS. 3 a, 3 b and 3 c, the set of plates 20 may include plateshaving two different shapes and configurations. A first category ofplates 20 a (FIG. 3a ) may be flat while a second category of plates 20b (FIGS. 3a and 3b ) may be creased, wrinkled, cupped, distorted orformed in such a way as to deform the plate permanently in sectionacross the largest plane. The deformation is induced to provide a springeffect in the axial direction 40 (FIG. 3c ). The first and secondcategories/types of plates 20 a, 20 b may be alternately disposed in theset of plates shown in FIG. 1. Accordingly every other plate wouldbelong to the second category of plates.

The springiness of the plates 20 b separates the alternately stackedflat and sprung plates 20 a and 20 b through virtue of the inherentlycontained elastic deformation of the non-flat plates 20 b. The resultinginter-plate gaps 22 promote the ingress of the working fluid 18 toprovide a film of roughly equal thickness between each pair of adjacentplates 20 through capillary action. It is understood that the conditionsrequired to be dampened, the viscosity of the fluid, the volume ofworking fluid confined between each plate 20 in relation to the escapearea at rest, the input force, the input velocity, and the number ofworking fluid interstices, all contribute to the behavior of thedampening. However, in general, a film thickness of not more than 0.050inches per gap, and more typically 0.010 inches per gap is adequate.

According to another embodiment, all the plates 20 could be flat, andthe separation of the plates could be achieved by springs (not shown),or suitable porous media disc or elastomeric separators interspersedbetween the plates 20, or any device which would promote the separationof the plates 20 to accept the ingress of the working fluid to therequired film thickness between the plates 20. For instance, separatorscould be made in the shape of starfish with a hole to guide the lot onthe shaft 34. The radial slots provided by spaces between the fingerswould promote the capillary refilling of the spaces 22. Cloth or someother similar porous material might also be used to promote wicking ofthe fluid back between the plates 20.

Allotment of space either radially outwardly of the plate circumference,or inwardly through the plates 20 by virtue of perforations (not shown)in each plate 20 or through a center hole defined therethrough, isprovided to allow egress of the working fluid 18 as the plates 20 areforced together under the action of the movable first force transmittingmember 24 on the working fluid 18. According to the embodimentillustrated in FIG. 1, when subject to a compression load, the workingfluid 18 is squeezed out from between the plates 20 in a radiallyoutward direction and the volume of fluid displaced is stored by radialinflation of the elastomeric boot 28. However, as mentioned above, it isunderstood that the working fluid 18 could as well be squeezed out frombetween the plates 20 in a generally axial direction throughperforations defined in the plates 20.

The working fluid 18 may be provided in the form of mineral oil.However, it is understood that other hydraulic or viscous fluids couldbe used as well. For instance, any of the following fluids might besuitable, having considered other aspects of construction, namely platearea, number of plates, thickness of the film at rest, requireddampening force and/or travel duration: Glycerine, glycol, grease,vegetable oil, emulsions of water and oil, water-alcohol. This is notintended to constitute an exhaustive list. Gases could also be used forcertain applications.

It is understood that the dampening characteristics vary as a functionof the viscosity of the fluid, due to the conversion of the input energyto heat through molecular friction of the fluid being forced outlaterally along the face of the plates 20. Furthermore, as the inputvelocity increases, or the inter-plate space decreases, the rate ofconversion is higher due to the higher molecular shear acting on thefluid. Intuitively, more viscous fluids would provide greater forcedampening at lower velocities. Mineral oil is chosen principally for itsappropriate viscous properties and is given due consideration forthermal viscosity stability, chemical stability, chemical compatibility,corrosion inhibition, extreme pressure lubrication characteristics, andothers. The volume of working fluid 18 is generally, but notnecessarily, free of dissolved gasses, including air. Once loaded in thehousing 12, the working fluid 18 is sealed from the atmosphere andprevented from acquiring atmospheric gasses by the hermetic chamber 14formed by the elastomeric boot 28 and the end members 24 and 26. Theprevention of the re-acquisition of atmospheric gasses into the degassedfluid by the hermetic elastomeric boot 28 aids in the prevention of theformation of cavitations bubbles. This would promote the flatter dynamicresponse through all operating conditions by assuring that the fluid'sflow characteristics from the inter-plate spaces 22 would remainconstant.

In use, the damper will typically be mounted between a fixed object andan object that is movable with respect to the fixed object. Forinstance, the first member 24 could be connected to the movable object,while the second member 26 is connected to the fixed object. When aforce or load F is applied on the first member 24, which in this caseacts as working or force transmitting member, the same will be axiallydisplaced towards the second member 26 (i.e. the reaction member)against the working fluid 18. The action of the first member 24 on theworking fluid 18 will cause the plates 20 to be axially pushed againsteach other from top to bottom. Since each plate 20 has little mass inrelation to the input force, the response to input forces isquasi-instantaneous through the stack of plates 20, where each platewill seek to maintain a hydraulic pressure balance between itself andits two neighbours. The thickness of the fluid film is expected to bereduced in thickness equally between all plates generallysimultaneously.

As a result, the working fluid 18 between each pair of adjacent plates20 will be squeezed out from between the plates 20. The volume ofworking fluid that is displaced as a result of the collapsing of theplates 20 will flow radially outwardly from the periphery of the platesand stored by the inflation of the boot 28.

As can be appreciated from the foregoing, when a load is applied to thecushion or unit 10 from an at rest position, the plates 20 are forcedcloser together. This reduction in distance causes the fluid 18 to beforced out from each inter-plate space. The reaction force resisting thecollapse of each fluid film (e.g. oil film) is produced by the volume offluid between each plate being forced to flow radially out of therelatively small escape area. The escape area is defined by thecircumference of each plate multiplied by the escape thickness. The areaof each plate face defines the active surface against which thehydrostatic forces will bear to resist the collapse of the cushion. Thereaction force is defined by the surface area of one plate multiplied bythe average hydro-dynamic pressure set up by the fluid flow escaping theplate gap. The hydraulic pressure on the fluid near the escape area isless than that on the fluid further into the plate, due to thepyramiding effect of the resistance to flow. The forces acting on eachplate 20 is on a plane parallel to the thickness of each plate, and isinduced by the friction of the oil sliding along the plate surface. Eachplate is loaded in tension parallel to the face. Since all plates 20 arefree to move independently of each other, they will seek to balancethemselves against each other in a direction perpendicular to the faceof each plate 20. Thus, the reaction force of any one will fairlyrepresent the force on any other. The force input into the cushion willbear ultimately on the inner faces of the two counter-acting members 24and 26. Only these two are constructed to withstand the sum of themechanical forces input into the cushion. If the collapse velocity isconstant, the reaction force will increase exponentially as the cushionis collapsed due to the ever decreasing escape area offered to the fluidversus the same pumping area. If the cushion is collapsed with aconstant force, the velocity will slow progressively until there iscontact between all plates. This velocity-dependent self-compensatingcharacteristic makes the graph of force versus time of a deceleratingload tend to have a vertical entry force, a flat-topped decelerationprofile, and a tapering finish, until the input force is equal to theinherent spring force of each plate, or the point where the plates touchcompletely. The force multiplied by the distance traveled will dictatethe amount of energy converted to heat through molecular friction of thefluid.

The ratio of the effective area of the working face of each plate 18versus the fluid escape area as measured along the circumference of theplates 20 multiplied by the thickness of the oil film between the plates20 provides a non-linear increasing reflected force damping behaviour ofthe hydraulic damper as the film thickness collapses.

The dampening characteristics are self-compensating by virtue of therelation between the plate effective surface area and the escape arearatio. If the entry velocity is high from an at rest position, thestroke distance available is large and provides time to decelerate theload. If the entry velocity is low, the damper 10 acts soft due to thedecreasing force per unit area acting to force the working fluid 18 outof the inter-plate gaps 22. As the stack of plates 18 collapsed and theload velocity slows down, the thickness of each oil film is less, andtherefore the ratio of the pumping area (i.e. the effective surface areaof the plates) versus the escape area of the confined oil iscorrespondingly higher. This higher reflected force at differing thereduced thicknesses causes the damper 10 to have a nearly flat reflectedload curve in decelerating kinetic masses.

The kinetic energy input into the damper 10 is converted to heat byvirtue of the molecular friction of the inordinately large effectivesurface area provided by the sum of the effective surface area of allthe plates 20, when forced to bear in friction with the relatively thinfilm of working fluid 18 moving laterally across the compression facesof the plates 20. Indeed, the sum of the effective surface area of allthe plates 20 provides for a total effective surface area which issignificantly larger than the effective surface area of a conventionalhydraulic damper having a cylinder with a sliding piston inside. Inother words, the set of plates 20 have a cumulative damping effect.

The relatively large effective surface area of the plates 20 provides arelatively high reaction force, which is generated perpendicularly tothe compression or working face of the plates, while keeping the forceper unit area acting on any of the internal working parts to arelatively low value. Large forces can be attenuated in small packagedue to the nature of the operation of the unit, in that neither sealsnor pressure vessels are required to contain the hydrostatic forcesfound in conventional piston and cylinder dampers. Instead, the forcesare contained between balanced working surfaces provided by the plates20 and the end members 24 and 26.

Contrary to conventional cylinder and piston type dampers which requirea seal between the piston and the cylinder, the damper 10 does notrequire any high pressure seal and is substantially friction free, whichmakes it reliable. The absence of static seal friction makes the damper10 more sensitive/responsive to small variations in input loads. Thedamper 10 is also advantageous in that the reflected load characteristicas seen through the damper converts much of the input energy to heat,and spreads the remaining force over time. This phase shift greatlyreduces the effects of transient force peaks, thus protecting down-lineequipment from high intensity short duration overloads.

FIG. 4 illustrates how two sets of damping plates 120 a and 120 b can bemounted back to back in one unit 100 to provide a double-acting damper.According to this embodiment, the housing 112 may be composed of acylinder 128 having an open end sealingly closed by a cap 126 to form achamber 114 filled with the working fluid 118. As shown in FIG. 4, thecap 126 may be threadably mounted or otherwise suitably secured to theopen end of the cylinder 128. A spool 124 including a shaft 124 a and acentral piston head in the form of an annular flange 124 b is mountedfor reciprocal movement inside the cylinder 128. The annular flange 124b provides two opposed working surfaces 125 and 127 so thatbi-directional loads input into the unit would be born against thehousing 112 through the two sets of damping plates 120 a, 120 b. Thecircumference of the annular flange 124 b may be less than the insidediameter of the cylinder 128 to allow the working fluid 118 to pass fromone side of the flange 124 b to the opposed side thereof. Alternatively,this may be accomplished by providing holes through the flange 124 b. Afirst end of the shaft 124 a extends outside of the housing 112 througha central hole defined in the closed end wall of the cylinder 128. Thefirst end of the shaft 124 a is adapted to be connected to a surroundingstructure requiring damping. A first seal 144 a may be mounted in thecentral hole to prevent the working fluid 118 from leaking out of thechamber 114. The second end of the shaft 124 a of the spool 124 isslidably received in a corresponding central recess 136 defined in theinwardly facing surface of the cap 126. A second seal 144 b may beprovided in the recess 136 to prevent the working fluid 118 from flowingaround the shaft 124 a into the recess 136. A vent 146 is defined in thecap 126 for allowing the air trapped in the recess 136 behind the secondend of the shaft 124 a to communicate to atmospheric pressure. To keepthe seal pressure at relatively low values, a cross-bleed flow passage148 may be defined centrally axially through the shaft 124 a with aseries of radial holes 150 a, 150 b at or near the seal points. In thisway, some of the working fluid 118 at a working-end seal can bleed backthrough the shaft 124 a to the non-working end. Since the inlet of thecross-bleed passage 148 is at or near the seals 144 a, 144 b, thehydrostatic pressure required to force the working fluid 118 radiallyout from between the damping plates 120 a, 120 b is not compromised, andeach plate stack behaves normally.

The first set of damping plates 120 a is loosely mounted on the shaft124 a between the closed end wall of the cylinder and the annular flange124 b of the spool 124. The second set of plates 120 b is looselymounted on the shaft 124 b between annular flange 124 b and the cap 126.The plates of both sets are free to axially move relative to the shaft124 a. Each plate 120 a, 120 b is spaced from an adjacent plate by afilm of working fluid 118. When the plates of a given set are forcedtogether, the working fluid between the plates will be squeezed outradially outwardly from between the plates and allowed to flow to theother set of plates on the other side of the flange 124 b. For instance,if an axial force F′ is applied on the spool 124, the working face 127will move the working fluid located between the flange 124 and the cap126, thereby forcing the stack of plates 120 b to collapse. The workingfluid 118 squeezed out from the stack of plates 120 b will flow past theouter circumference of the flange 124 b to the stack of plates 120 alocated on the other side of the flange 124 b. The working fluid flowingto the set of plates 120 a will cause the plates 120 a to be spreadfurther apart. The pressure differential between the compression ofplate stack 120 b and the expansion of plate stack 120 a will cause thefluid to flow into the voids between plates 120 a. Capillary actionwhich permits the fluid to flow into the voids will be aided by theinherent spring force in whichever plate 20 b is deformed. In time, thecapillary action and the inherent spring force will cause the oilthickness between each plate to be equal in thickness throughout platestack 120 a.

The need for an elastomeric expansion chamber in this second embodimentis obviated by the equal displacement of either end of the spool 124.Since the internal volume of the unit remains the same regardless of theposition of the spool owing to the double-rod arrangement, the fluiddisplaced from plate stack 120 b is hydrostatically compelled to fillthe void in plate stack 120 a.

The variant of internally or externally mounted springs to accomplish apre-load condition can be achieved in a variety of ways. FIG. 5illustrates one possible configuration of an internally pre-loadeddouble acting unit 200. In the embodiment of FIG. 5, a set of internalsprings 225 a and 225 b tuned to the lower threshold load are mounted tobear against a double flanged spool 224 and a central partitioning disc231. The spool 224 has first and second flanges 224 b and 224 b′. Thepartitioning disc 231 is mounted between the first and second flanges224 b and 224 b′. The first spring 225 a extends between the firstflange 224 b and the partitioning disc 231 to bias the spool 224 towardthe left-hand side in FIG. 5, while the second spring 225 b extendsbetween the partitioning disc 231 and the second flange 224 b′ to biasthe spool 224 towards the right-hand side in FIG. 5. The first flange224 b has a working surface 227 facing the end wall of the cylinder 228.Likewise, the second flange 224 b′ has a working surface 229 facing thecap 226 closing the open end of the cylinder 228. A first set of dampingplates 220 a is loosely mounted on the spool shaft 224 a between theworking surface 227 and the end wall of the cylinder 228. A second setof damping plates 220 b is loosely mounted on the spool shaft 224 abetween the working surface 229 and the cap 226. The spaces betweenadjacent plates (i.e. the inter-plate gaps) are filled by the workingliquid 218 just like in the other embodiments. The partitioning disc 231is held in the middle of the chamber 214 between tubular spacers 264.The cap 226 axially retains the spacers 264 and, thus, the partitioningdisc 231 in position in the chamber 214. With the springs 225 a and 225b in slight pre-tension, any external load acting axially on the spoolshaft 224 a would have to overcome the tension of the springs 225 a and225 b before causing the space confining the set of plates 220 a, 220 bto change. For instance, to move the spool 224 to the right in FIG. 5,the biasing force of the first spring 225 a has first to be overcome.Then and only then, the spool 224 can be moved to the right to cause thesecond stack of plates 220 b to be pressed against the cap 226, therebycausing the working fluid to be squeezed out from between the plates 220b. The working fluid displaced by the motion of the working face 227 ofthe second flange 224 b′ is allowed to flow to the idle plate pack 220 athrough axially extending passages 270 defined in the partition disc231.

The spool 224 is assembled generally, but not necessarily, by a centralscrewed shaft connection 237 between the flanges 224 b and 224 b′,thereby allowing the assembly of the partition disc 231, the two springs225 a and 225 b, and the spool halves inside housing 228. The oppositefaces are engaged when the spool 224 is moved to the left. Springs ofdifferent strengths can be employed to have different breakaway forcesin extension or compression of the unit. Since the springs 225 a and 225b hold the spool 224 centered in the housing and motion is preventeduntil the spring force is overcome by an input force, the unit can beused to act as a breakaway overload when the unit is used in line in aposition-dependant mounting. This variant could be built as a single ordouble acting.

As shown in FIGS. 6 and 7, hydraulic damping units 300, which may eachbe similar to unit 10 shown in FIGS. 1 and 2, may also be used toprovide torsional damping. The torsional damping assembly shown in FIGS.6 and 7 may, for instance, comprise a pair of discs 302 and 304drivingly connected for joint rotation about an axis 301. The first disc302 has a series of circumferentially spaced-apart slots 306 definedtherein. Each slot 306 extends along an arc of circle. The second disc304 has a first series of circumferentially spaced-apart fingers 308extending perpendicularly from one face thereof for engagement in theslots 306 of the first disc 302. A pair of individual damping units 300is mounted at opposed ends of each slot 306 with one finger 308 engagedtherebetween. A second series of circumferentially spaced-apart slots312 is defined in the disc 302. The second set of slots 312 is angularlyoffset relative to the first set of slots 306. As shown in FIG. 6, eachslot 312 is disposed between two slots 306. In addition to the dampingunits 300, a pair of coil springs 310 or the like may be mounted in eachslot 312. A second set of circumferentially spaced-apart fingers 312projects from disc 304 for engagement between each pair of springs 310.The springs 310 provide a lower threshold breakaway force. The springs310 will provide the torque characteristic for normal drive force, andvariations in driving torque between the discs 302 and 304 which exceedsthe spring force would be dissipated into the damping units 300.

As shown in FIG. 8, the damping units 10, 100 or 200 could also be usedas hydraulic cylinder end-stop cushions. For instance, a damping unit400 can be mounted inside the cylinder 402 of a hydraulic cylinder andpiston arrangement 404 to cushion the linear motion of a ram 406. Thedamping unit 400 may comprise a plunger-like member 405 having a headportion 408 and a shaft portion 410 extending perpendicularly from aworking face 412 of the head portion 408. The distal end of the shaftportion 410 is axially guided in a bore or recess 414 defined in the endwall of the cylinder 402. A set of damping plates 416 is freely mountedon the shaft portion 410 of the plunger-like member 405. The axial gapsbetween the plates 416 are filled by the hydraulic fluid used to actuatethe cylinder 402. The diameter of the head portion 408 of theplunger-like member 405 and that of the plates 416 are generally smallerthan the inner diameter of the cylinder 402. When the ram 406 reachesthe end of its stroke, it axially pushes against the head portion 408 ofthe plunger-like member 405, thereby axially displacing the head portion408 to bear force onto the plate stack. The action of the working face412 of the head portion 408 of the plunger-like member 405 causes thepack of plates 416 to collapse, thereby squeezing out the oil frombetween the plates, as described herein before. Cushioning could also beprovided at the end of the return stroke by mounting a second unit 400′onto the rod-end of the ram, as shown in FIG. 8. The second unit 400′may comprise an annular flange 408′ fixedly mounted on the rod-end ofthe ram 406 and a stack of plates 416′ freely mounted on the rod-end ofthe ram 406 between the annular flange 408′ and the end wall of thecylinder 402.

The above arrangement provides an interesting alternative to the currentpractice which typically consists of providing a tapered plug onto theend of the ram for engagement in a hole of close fitting tolerances inthe end cap of the cylinder to provide hydraulic pumping through abraking orifice. To move the ram out of the cushion of this formrequires a machined port with a flow check valve allowing oil back intothe space behind the tapered plug, as the plug recedes. The advantagesof the above proposed alternative comprise: simplicity, reducedmachining, elimination of the required breakaway retraction forcetypical to lifting the flow check off of its seat, reduced mechanicalsize requirements, and improved damping at varying loads and velocitiesdue to the self-compensating nature of the illustrated embodiment.

As shown in FIG. 9, the cylinder end-stop variant could be adapted toair cylinders as well. In adapting the cushion or damping unit 500 toair cylinders, an elastomeric envelope 502 would be provided to containthe working fluid. For instance, a unit similar to the unit shown inFIG. 1 could be used. The rod-end unit or return stroke unit 500′ wouldcomprise an elastomeric seal to both the outside periphery 504 and theinside periphery 506 of the hole in the stack of plates.

FIG. 10 illustrates one possible dead-blow hammer application. Thehammer 600 has a hammer head 608 comprising a mass 602 mounted betweentwo hydraulic damping units 604 inside a cylindrical tube 606 andretained captive therein by any appropriate means, such caps threadablymounted to oppose ends of the tube 606. An internal passage 610 allowsthe exchange of the displaced working fluid upon the collapsing of theplate packs 612 of the units 604 to the opposite end of theacting/solicited damping unit. The damping units 604 could, forinstance, take the form of any one of the embodiments shown in FIGS. 1to 5. It is also understood that the specific assembly configurationshown in FIG. 10 is for illustrative purposes only and that there aremany other suitable ways to incorporate a hydraulic cushion or unit intoa hammer head.

As exemplified in FIG. 11, the mounting of a hydraulic cushion or unit700 to the bottom end of each leg 702 of furniture, and mostly to thoseof chairs and tables would provide instantaneous intervention-freeself-adjustment of the object to minor localized varying floor levels,as are commonly found on tiled flooring surfaces. Each unit 700 could,for instance, be of the type shown in FIGS. 1 to 3. The inherent springforce produced by the distorted plates 704 of the type shown in FIGS. 3band 3c would produce a reaction force which would be tuned to a valueless than the normal unloaded object weight, and upon being placed ormoved to a floor location which was uneven, would cause the least loadedleg cushion 700 to extend by virtue of the reduced load, or the mostloaded leg cushion 700 to compress by virtue of the higher load. If anoccupant shifted the load, say on the corner of a table, the two legs,generally diagonally opposite from each other with the higher load,would already have collapsed to their shortest distance, the thirdpoint, now under the elbow of the occupant, would collapse slowly, andavoid upsetting the table suddenly, and the fourth, now unloaded legcushion would extend to take up the distance made available by theretreating leg. If the object load was to change again, or if the objectwas changed to a different position on the floor, a new balance would beestablished without rapid motion in the object being permitted.

According to another possible application, one or more force limitingdevices, such as the one shown in FIG. 1, could be used as aself-adjusting vibration dampening machine base. For instance, forcelimiting devices 10 could be added to the bottom extremities of domesticappliances prone to vibrate, like the domestic clothes washing machine.Each force limiting devices could be force-tuned by the use of springs,or by the inherent spring force of the sprung plates, to thegravitational load normally exerted by the machine at rest. The springrate would hold the cushion at rest in a partially collapsed state. Theuse of the devices would allow the machine to settle like the restauranttable, where the two opposite legs more highly loaded would collapse totheir shortest distance, except that due to the force tuned internal orexternal springs, the devices or cushions would not bottom out at rest,but instead be held by the action of the spring at a collapse distanceallowing further collapse if the force system was increased dynamicallyby the function of the machine.

A good example of use would be the spin cycle of the clothes washingmachine. At rest, the cushions would settle to provide quasi-even forceon each leg, regardless of minor localized level discrepancies of thefloor, by virtue of the spring action. Once the machine began tooscillate from operating, the shear friction of the oil being forced outof the plate interstices would dissipate the energy of the machineoscillations. Furthermore, the self-compensating characteristics of thedampening effect will auto-tune the force limiting device to thefrequency of oscillation seen by the machine, and tend to limit thesympathetic resonance of the machine as it accelerates through thecritical speed. Another aspect of the benefit of incorporating thedevice into the base of machines would be the attenuation and/orsuppression of noise which would normally be transmitted to the floor;the floor acting as a radiating surface which converts the vibrationsinduced upon it by the machine, to sound waves in the space. Since theforce limiting device auto-tunes to a wide range of frequencies, asubstantial reduction in sound transmission can be achieved.

As shown in FIG. 12, the force limiting devices could also be configuredto act as shock absorbing cushions in protective helmets, such as thoseused in practicing sports. Indeed, it may be possible to reduce physicalharm to sport players by incorporating several cushions 804 into ahelmet, as shown in FIG. 12. The incorporation of cushions 804 betweenthe hard inner working surface 809 of the helmet and of the cranium 831of the person wearing the helmet provides concussive protection to thehead of the wearer. Each cushion 804 may comprise a hermetically sealedfluid filled bladder 811 mounted to surface 809 and containing amultitude of free floating plates 817, which may be made of flexibleplastic material, interspersed with cloth sheets 823 of equal size. Atrest, capillary action promotes the equal distribution of fluidthroughout the thickness of the cushion by wicking into the cloth, andthe cushion thickens to a point of hydraulic equilibrium between thecranium and the helmet. This characteristic of behavior would constitutea self-adjusting helmet, so that localized individual cranial variationsof the wearer would be supported equally by the combination of the innerworking surface of the helmet and the quasi-liquid state of thenon-compressed cushion. When a concussive force F is applied by hittinganything with the helmet, the fluid which was contained between eachplate would seek to escape laterally to the edge of the cushion. Sincethe cushion is self compensating by virtue of the increasing resistanceas the cushion collapses versus the diminishing force applied typical todeceleration, the perceived peak force remains relatively constant butis extended over time, and is thus limited in intensity. This dynamicdeceleration will help to reduce concussive forces applied to sportsplayers, and thus limit immediate and long term trauma to the head.

As can be appreciated from the foregoing, the present invention isparticularly suitable for attenuating any unidirectional or reversingload of great intensity and short duration. For instance, it could beused as entry cushions for load cells, where the collision of massesthrough load sensing instrumentation sets up large transient spikes,dangerous to the maximum operating limit of the load cells. It couldalso be advantageously used in linear acting machine requiring a rapiddeceleration. Railway end-of-line bumpers made of this configurationwould be useful in protecting the end-of-line bolster. It could also beused on machine bases or component mounts where the use of springs orelastomeric mounts to support the mass gives rise to deleterious baseharmonic frequencies. By having a portion of the energy converted toheat, the settling time of the harmonic would be shortened. The use offrequency-tuned dampers in aerospace would aid in attenuating dangerousor problematic harmonics or peak-force transients.

As will be seen hereinafter, the compensating device could also beadapted for use as: a gun recoil pad (FIG. 13), a machine vibrationisolation base (FIG. 14), an energy dissipating mounting link (FIG. 15),and an electronic component shock dissipating mount (FIG. 16).

With respect of the gun recoil pad application, it is noted that thereare already recoil pads made of porous elastomeric materials which aremounted on the butt-stock of guns which serve to compress somewhat andreduce the rate of energy transmission of the recoil event to theshooter's body. However, there remains much room for improvement.

As shown in FIG. 13, the incorporation of a compensating damper of thetype described herein above into a butt stock recoil pad 1003 provides amarked and substantial reduction in the physiological harm of shootingshoulder mounted guns, serves to improve accuracy by helping overcomethe psychological flinch, allows more rapid and accurate firing byreducing the time required to overcome the physiological reaction toeach event, and by sequestering a substantial amount of the recoilenergy as molecular friction in the compensating damper, reducing thetime and distance of the rock-back required to reposition the gunaccurately for the next shot.

The dynamics of shoulder fired guns produce a force quasi-collinear withthe axis of the gun barrel, and reacting opposite to the direction ofthe projectile and ejecta. The energy of the projectile and ejecta beingaccelerated forward act against the mass of the gun, (and in some cases,minus the work done by mechanisms used to actuate the gun's cockingmechanism) produces in the mass of the gun, a velocity backwards towardsthe shooter. This event is known as recoil. The shooter is required toabsorb the energy of recoil through the viscous friction of the tissuesof the body, and the input of muscular effort to counter the force. Themechanical connection of the reaction force from the gun to theshooter's shoulder is the physical area of gun butt stock in contactwith the shooter's shoulder at the time of initiation of the event.Since the time required to produce muscular counter resistance isrelatively slow in human terms when compared to the speed of the recoilevent, the initial recoil event behaves in classic Newtonian fashion; amass moving at a certain velocity impacts another mass, and imparts itsenergy to the receiving mass; the elasticity of the connection and thefluidity of the receiving mass dictate the rate of acceleration of thereceiving mass. Whereas the time the expulsion of the projectile andejecta takes, say, 3 milliseconds, the human muscle reaction time is inthe order of 200 milliseconds or more. Clearly, the entire energy inputevent is over before the shooter can react, and the initial resolutionof the recoil force is seen as a shock wave propagating through theflesh of the shooter. This shock wave as it travels through the fleshcauses molecular friction and results in a substantial portion of theenergy being converted to heat.

In order to anticipate the blow of the recoil while pulling the trigger,some shooters involuntarily flinch to protect themselves. This affectsshooting accuracy by adding erratic muscle contractions or by loadingopposing sets of muscles in tension and causing muscle strain inducedmovements. Another negative aspect of shooting guns is the physiologicalharm done to the shooter when using large bore, high power rounds. Thehigh recoil forces cause tearing of the human tissue, bruising, sorenessand future apprehension in shooting.

It is classically trained to hold the gun tightly to the shoulder inanticipation to the recoil. While this strategy reduces the felt recoilby increasing the muscle-induced mass-coupling to the system, the forceper unit area between the gun butt stock and shooter's shoulder willultimately be higher. This muscle strain also contributes to shaking ortwitching as the trigger is pulled, leading to a loss of shootingaccuracy.

Another objectionable aspect of the coupling of the butt stock's energyto the shooter's shoulder is the relatively high shear force acting onthe tissue at the corner of traditional gun butt stocks. Since thetissue at these velocities and forces behaves as a viscous fluid, theacting area of the butt stock causes all of the tissue behind the buttstock to flow, and localized rending of the flesh as the shock wavewraps around the corner of the now-advancing butt stock into the tissue.This localized rending breaks blood vessels, stretches tendons andmuscle, tears nerves, and causes bruising. As the shock wave propagatesradially, more and more tissue mass is added to the equation, includingbone and connective tissue. As more tissue reaches its maximum normalextension, the active tissue mass involved in decelerating the gunincreases, and reaches a point of velocity equilibrium where the gun andshooter begin to move as one. This state of velocity equilibriumgenerally causes the shooter to rock back, and is now within thereaction time of the human animal to counter the momentum and return thegun to the original position. Apart from the muscle effort required toright the body and gun back to the original position, the recoil energywas absorbed into the tissue through molecular friction.

FIGS. 13a and 13b illustrate another embodiment of compensating dampersuited for use as a new gun recoil pad 1003. However, it is understoodthat the features of this embodiment could be used in other applicationsor combined with features of other herein described embodiments. The gunrecoil pad 1003 comprises a series of alternately stacked wavy and flatplates 1007 held inside a chafe resistant open weave mesh bag 1012, andinserted into a hermetically sealed elastomeric boot 1023 approximatingthe cross-section of the butt stock of a gun 1034. The boot is closed atthe end normally against the butt stock of the gun by two plates 1037clamping the elastomeric boot by means of screws 1038, and having teethor grooves 1041 in the faces of the plates making certain the mechanicalconnection. The boot 1023 is filled with a viscous fluid 1056 preferablybut not necessarily glycerine, and pressurized to cause the boot wall tobe distended somewhat 1066. This internal pressure acting to causetension in the boot allows the pad to be more rigid, while permittingthin wall sections of the boot 1023 which are needed to stretch duringthe recoil event. The entire bladder now being rounded outwards by theinternal pressure of the fluid causes the end which the shooter putsagainst his shoulder to be lifted away internally from the plate stack1079, and have a fluid thickness there of about ⅛″ or more. The mesh bag1012 holds the spring action of the plates 1007 to a set maximumextension distance with, typically 0.015″ to 0.030″ distance per gap. Inother words, the mesh bag 1012 holds the plates to a stack height ofabout ¾″, and the internal bladder distance has about ⅞″ of internalspace when distended by the fluid pressure. This free fluid, while beingseemingly inconsequential to the operation of the damper plates proper,contribute to the recoil pad damper's operation, and provides hydrauliccushioning to the shooter's tissue principally as the recoil eventbegins.

For all the contemplated embodiments, there can be more than one filmthickness across the stack of plates. Each of the varying film thicknesszones provides a different resistance response when acted upon by anoutside force. Generally, when there are two different film thicknesszones, the first one to collapse is the thicker one, owing therelatively low lateral flow resistance offered by the wide gap.Conversely, if the structure of the unit holds two or more sets ofplates or gaps of fluid, the one with the smaller gaps would only beginto collapse once the larger zone of gaps had reached nearly the samethickness as the thinner gap zone or hydrodynamic equilibrium to thethinner film zone is reached, whichever occurs first.

For gun recoil applications shown in FIGS. 13a and 13b , each zone offluid film thickness contributes benefits to a different operationalphase of the recoil pad's deployment; the thicker fluid film nearest tothe shooter acts first to provide balanced force between the shooter andthe plate stack proper. Progressively as the thicker film flows out andbecomes equal to the inter-plate pressure, the inter-plate gaps begin toprovide high fluid shear energy conversion as the inter-plate gaps forcetheir fluid out laterally across the plate faces into the expandingboot.

The density of the fluid and the elasticity of the elastomeric boot arechosen for their approximation to the density and elasticity of flesh.In that way, when the shock wave of the butt-stock begins its excursioninto the shoulder of the shooter, the force transition interface betweenthe recoil pad and the shooter's tissue is transparent. In other words,the bladder will mold itself to the resistance offered by the flesh andadjust itself by redistributing fluid from zones of high force-per-unitareas to zones of low force-per unit areas. This fluid distributionkeeps the force averaged at any point to be the lowest possible. Also,the high shear force exerted at the corner of traditional butt stocks asthey incur into the tissue are virtually eliminated. The shock wave ofthe advancing recoil pad, owing to the flattening out of the bladderwill for a short duration expand to be larger than the original bootcontact area by a considerable amount. An increase of 2 times theat-rest area is not uncommon, depending on the parameters of thedampening plates as they behave at the given recoil force level, themass and muscle pre-tensioning of the shooter, the recoil velocity ofthe gun, the mass of the gun, the elastic stiffness of the recoilbladder, the viscosity of the fluid chosen, and other factors.

Furthermore, as the boot 1023 flattens out from the force, the shockwave rolls the contact patch ever wider, and redirects the shock wave toblend into the tissue perpendicular to the recoil direction, and travelparallel the surface of the shooter's skin. This gradual lateralre-direction of the shock wave as the boot rolls sideways, lowers thepeak force in the tissues adjacent to where a traditional butt stockwould cause the greatest amount of shear.

As the recoil pad 1003 collapses and the fluid pressure becomes balancedbetween the shooter and the first plate in the plate stack, the plates1007 being relatively thin, will flex to follow the contour offered bythe resistance of the shooter's particular anatomical features such asbone and tendons, and will further redistribute any point loading on thetissue.

Since the fluid in the inter-plate gap is forced to flow along the faceof each plate 1007, and as the exit gap gets smaller by the collapsingplate stack, the reaction force caused by the escaping fluid increasesexponentially as the cushion gets shorter. This increasing damperstiffness compensates for the decelerating velocity of the gun andmaintains the deceleration force at a more constant level throughout theduration of the event. This provides for a self-compensating effect asdescribed herein before with respect to other embodiments.

Since the total recoil energy is either dissipated into molecularfriction, or as muscle effort to return the gun to the pre-eventposition, it is evident that by removing some of the energy as molecularfriction in the recoil pad, the law of conservation of energy statesthat the rock-back motion will be decreased, and also, that the shooterwill not have as much energy dissipated into the body.

Tests show a ⅙ or greater reduction in the rock-back position of theshooter. The highest recoil velocity of the event happens at the pointwhere the projectile has left the gun, and the ejecta have reachedatmospheric pressure. High speed video investigation of a high poweredrifle shows that the ejecta have reached a state of equilibrium whilethe gun has travelled backwards not more that ⅛″. This means that theshooter's flesh which would receive the recoil force without the recoilpad would only compress ⅛″ before the recoil velocity of the gun was atits highest. In tests, a typical shotgun recoil velocity was measured tobe 18 feet per second, and presumably, the shooter's flesh next to thegun's stock would be subjected to the G force commensurate with thatacceleration. With the recoil pad in place, while the gun recoilvelocity remained at 18 feet per second, the shooter's shoulder wasmeasured to be accelerated to only 8 feet per second. Half theacceleration equals ¼ the energy, and the increased bearing surface onthe shooter due to expansion of the fluid filled boot provides comfortin use.

There are several mounting methods currently used to mount recoil padsto shoulder fired guns. These include most simply screwing a rubberblock or other form of padding to the gun stock with two screws. Othermethods of holding the pad to the stock, and especially on hollowconstruction composite gun stocks, might be to cause mechanicalinterference between the pad and the stock with a bead or dovetail ribmolded into the rubber pad engaging a bead or lip on the inside of thehollow gun stock section. On some hollow section composite stocks, thereare provisions molded into the plastic to accept screws. Gluing is alsoan option.

Shoulder fired guns tend to be fitted or chosen for the length of pullaccording to each shooter. Length of pull is the distance from thetrigger hand grip to the butt stock end rested on the shoulder. Thecorrect length of pull increases the accuracy of shooting by permittingcomfortable sight line alignment, having the recoil event be absorbed bythe shooter in a comfortable position, and other factors. Sinceadjusting the length of pull requires modification to the stock andsince the public has accepted a certain common length of recoil pad inconjunction with the store of guns in the public domain, and that alarge number of firearms in the public domain are currently fitted withthe accepted length of pad of 1¼ inches, adapting our compensatingdamper recoil pad as a replacement would best be accepted if the lengthof the unit was similar in length. Further, in the case of mounting thecompensating damper to shoulder fired guns, it would be beneficial tohave a mounting system which would take up as little length as possible,in order to provide the longest effective dampening stroke lengthpossible.

Since our compensating damper recoil pad is a fluid filled hermeticallysealed bladder; the use of screws through the package is not possible.FIGS. 18a to 18d illustrate a mounting system for mounting ourcompensating damper recoil pad to shoulder fired firearms (1801) andincluding a base plate (1803) made of but not necessarily aluminum,which has a center recess (1809) sized to accept the sealing plate(1821) of the rubber bladder (1824), which contains the plates and fluid(1827). The base plate is fitted with two or more lever cams (1830)which are permitted to pivot on rivets (1831), and which have a taperededge (1834) forming a cam ramp (1836). The sealing plate (1821) hasrecesses (1824) in the edge ready to accept the lever cam ramps (1836).The lever cams (1830) have an undercut (1839) which, when in the openposition (1841) permit the recoil pad (1802) to move past the lever camsupon installation. Conversely, when the lever cams (1830) are closed(1851), the cam ramp engages behind the sealing plate recess (1824), andholds the recoil pad against the base plate (1803). The cam levers(1830) are inset in a pocket (1862) which, when the lever cams areclosed (1851) fill the pocket very nearly (1867). The cam levers aremade of but not necessarily stainless steel, and add a design aspect tothe edge of the aluminum base plate by forming a line of dissimilarmetal colors (1870). The base plate is, but not necessarily, anodized tohave a dark blue color, meant to mimic gun bluing, which offsets thestainless cam lever color. The base plate (1803) has two slotted holes(1877) to accept screws.

In use, these screws mount the base plate to the gun stock (1881). Oncethe base plate is attached onto the gun, the recoil pad is then slidinto position with the sealing plate engaging the recess in the baseplate, and the cam levers pivoted to engage the cams behind the sealingplate recesses. The close tolerance between the sealing plate (1821) andthe base plate center recess (1809) makes all of the lateral dynamicforces encountered by the gun during the recoil event, or during thenormal transportation and handling of the gun transferred ultimately tothe screws holding the recoil pad to the gun.

Referring now to FIGS. 14a to 14c , it can be appreciated that acompensating damper with an inter-plate fluid film arrangement can beadapted for use as a machine vibration dampening base.

As shown in FIG. 14, a new conical form of arrangement of the platesallows dampening in more than one geometric plane at once. Thisarrangement may be applied to all embodiments herein described. Similarto the other embodiments, the dampening base has a hermetic chamber 1104filled with fluid. The plates are arranged to be alternately stackedwith every other plate being deformed as described hereinabove, but theform of the plates are cone shaped 1121. The plates are positioned in acup shaped receiver 1314, generally but not necessarily in the base, andare acted upon by a cone shaped plunger 1357 sealed to the cup with adiaphragm shaped membrane 1308. By adding externally adjustable springs1362, and by increasing the tension of the external springs by means ofjacking screws 1194 to have the same reaction force as the static loadplaced on the Machine Vibration Dampening Base (F), the internal traveldistance of the unit can be adjusted. By reducing the tension force ofthe external springs below the static input load on mounting stud 1332,the fluid is forced out from between the plates, and cone to cup contactis established through the plate stack 1355. This makes the unit behaveas one with the base, with no dampening action, and transmits thedynamic forces from the machine by mounting stud 1332 through a rubberring 1331 or the like to the floor. By increasing the force of theexternal springs to provide a state of equilibrium, zero buoyancy fromthe static vertical input load is achieved. An internal clearance in thedamper is then established if the mounting stud 1332 is subjected to adynamic machine induced vertical change in load, acting in the samedirection as the springs. The space vacated by the cone in thistransient vertical motion allows fluid to enter between the plates, andas the oscillation induced in the mounting stud returns to net zeroforce with the springs, the fluid once entrained into the plates getsforced out, generating a dampening action on the half cycle oscillationwhich caused the extension of the dampener. Adding further springtension causes the plates to have a fluid space at rest, and thus allowsthe unit to dampen if the load moves the cone closer or further to theplates and cup. Also, the cone shaped plunger will, if there is internalspace available, allow motion lateral to the axis of the cone, andcompress the oil films on one side of the cone. With the damper fullybuoyant with external spring force, when the machine encounters dynamicoscillations or transient changes in position the dampening will occurin all directions, be it co-axial or cross-axis to the cone by the fluidbeing forced out from the inter-plate spaces.

The externally adjustable tension of the springs permits the inter-plategaps of the dampening plates to provide more or less dampening at will.Since more space means retracting the cone further away from the cup, alarger orbit distance is permitted. The increased distance allows moreenergy to be dissipated per orbit by a longer dampener stroke, at theexpense of allowing more machine travel. Conversely, the peak force thatthe damper proper transmits to the floor will be higher as the maximumpermissible orbit is reduced. The perfect balance between maximum orbitand maximum force attenuation can then be easily established byadjusting the springs dynamically as the machine operates.

By varying the position of the cone vertically by increasing theexternal spring buoyancy, and by consequence making the allowable strokelonger, the machine would transmit less force through the damper buthave a longer range of motion. Conversely, if the dampening cone wasmade to run closer to bottoming out on the receiving cup by decreasingthe buoyancy of the external springs, then the total position orbit ofthe machine would be more tightly controlled, at the expense of reduceddampening effectiveness. A particularly good use for this embodiment isin the machine bases of vibratory bowl feeders, where the vibrationsignature of the machine by its very design transmits much energy to thefloor, and where maintaining a constant output position of the bowlfeeder is critical in maintaining the proper flow of parts to the nextmachine. Since the total orbit of the Multi-Axis Compensating MachineDamper can be externally adjusted by changing the spring force whileobserving the behaviour of the bowl feeder, then the best ratio ofdampening-to-position-keeping can be discovered merely by adjusting thetension on the springs.

The energy transmitted to the floor in some installations has beenreported to cause fatigue, and physical harm to the feet and legs ofoperators who must tend the machines for long periods of time and whomare subjected to the vibrations induced into the floor. In one casestudy, where vibratory bowl feeders were in use, the energy transmittedto the concrete floor could be felt in the entire production facility.Concrete floors are rigid in nature and the energy travels considerabledistances. Tests using the Multi-Axis Compensating Damper MachineVibration Bases showed a 94% decrease in energy transmitted to thefloor.

FIG. 15 illustrates a still further adaptation of the compensatingdevice. More particularly, FIG. 15 illustrates a compensating damperenergy dissipating link suited for use in a vehicle, such as militaryvehicles. The energy dissipating link or unit may comprise a sealedmetallic canister 1503 holding a stack of weavy and flat plates and withan external tubular wall of a thickness capable of supporting the normalstatic and dynamic forces of the occupant's cabin 1554 in heavy armoredvehicles; each unit may serve to act as the corner attachment point 1592between the pressure 1502 hull and the occupant's cabin 1554. Each unitcould have two internal working faces 1553 between which to hold thefluid filled flat plates 1562. One end could have a suitable joint topermit mounting 1511, while the other could have a rod type arrangementprojecting through the craftily machined end of the tube 1566. Thismachining detail in conjunction with carefully chosen metallurgies andheat treating, would form a weak point 1528 in the tube end which wouldcause a stress concentration point to fracture when a force exceedingthe normal operation of the vehicle, and in particular to the forcesencountered in an explosion were encountered, and allow the rod to berun into the canister 1591. This would permit gaining access to thedesired dampening effect. The fluid filling the canister 1558 could beconfined hydrostatically if the fluid consumed all the internal space,and hinder the weak point 1528 from breaking. A controlled volume ofinert gas 1594 in the initial filling of the unit provides acompressible internal space to permit the change in internal volume. Atthe point of fracture, the breech in the canister 1503 would permit thefluid escaping from the inter-plate gaps to flow out 1533. Biodegradablefluid, such as glycerine would normally be employed. One advantage ofthe sealed canister provides the maintenance free guarantee ofperformance of the unit only in case of a catastrophic force event. Theunit's dampening effect would limit the acceleration forces projectedonto the occupant's cabin and help to limit injuries to the occupantstherein by shielding the occupant's cabin from the direct accelerationof the blast and that of the pressure hull's acceleration. The extremelyhigh rate of energy conversion permits the integration of high capacityforce limiting devices in compact spaces.

FIG. 16 illustrates a still further possible application of aninter-plate film damping arrangement. More particularly, FIG. 16illustrate an electronic component shock dissipating mount which maycomprise a series of dampening units 1604, typically mounted at thecorners of a base plate 1611, and comprised of sets of opposed conicalform pistons 1615, sealed into an enclosure having opposed cup shapedinternal surfaces 1673, and sealed hermetically with an elastomericdiaphragm 1684. The base plate 1611 acts as a seismic mass suspended infree space by the dampeners, and connected through the dampers to themachine housing 1621. The base plate provides a chassis to which thesensitive electronic components are mounted 1667. In use, the baseplate, having inertia and being slung by the normally compliant dampers1615 exhibits a low base harmonic frequency. The mass of the base plateand of the electronics mounted thereto, in conjunction with thecompliant nature of the dampers at rest permit the relative orbit of themachine without inducing strong acceleration forces to the base plate.The configuration reduces greatly any vibration or transientaccelerations which the machine housing is subjected to, to acceleratethe base plate.

The plates 1644 may be generally conical in form. Each alternating platemay be deformed 1647 to provide inherent spring force. This springaction forces the plates to separate, allowing fluid to enter theinter-plate gaps. There are a series of plates in each cone assembly1615. The inherent spring force of the sum of the plates in all of thedampers provides enough force to overcome the mass of the plate and ofthe mounted electronic components, such that the space available forfluid between each plate is roughly equal, no matter which sense theobject is mounted in relation to gravity. In other words, the at-restposition of each conical damper pair is roughly centered in its stroke,so that any extraneous force acting to accelerate the base plate willcompress fluid out of the inter-plate spaces and, thus, dampen theforces acting on the base plate. Fluid normally displaced by theadvancing of the conical pistons towards the cups in one direction willflow to the other side.

Another aspect of this embodiment is the reticence of the base plate tooscillate in harmonic resonance to any outside frequency. This is due tothe high rate of molecular shear of the fluid as it is being forced outof the relatively thin spaces between the plates. The unit converts ahigh percentage of relative motion between the base plate and themachine base to heat. Tests show a conversion rate of motion to heat ofmore than 94%.

FIG. 17 illustrate an improvement over the embodiment shown in FIG. 1.As shown in FIG. 17a , the embodiment of FIG. 1 includes a series offlat plates 1701 mounted about a single central shaft 1704. Theembodiment shown in FIGS. 17b to 17e essentially differs from theembodiment shown in FIGS. 1 and 17 a in that the central shaft isreplaced with multiple pins extending from each working end plate 1723,and engaging the plate stack partially from each face 1733. As can beappreciated from FIG. 17a , one limitation of the single center shaftorientation is the stroke distance permissible 1706 in relation to thetotal length of the damper 1708. In the single center shaftconfiguration, the compressed plate stack thickness plus the total fluidgap thickness plus a reasonable guide shaft engagement length in thereceiving end working surface plus the stroke distance added to thereceiving end, plus the opposing working plate length, dictates theminimum damper length. The center shaft in this configuration mustproject past the distance taken up by the plate stack and engage theopposite working face, in order to guide the plates as the fluid isforced out of the gaps. The challenge is to provide as many plates aspossible in any given space. This optimization of plate thickness toenvelope size gives rise to the need for this new arrangement.

In the embodiment shown in FIGS. 17b to 17e , the plates are guided byan array of pins forming a hole-circle about the center of the plates1714, and the pins 1723 projecting from one working face of each endworking surface occupies every other hole 1712. The length of engagementof the pins into the plate stack of the damper at rest 1733 emanatingfrom one face are less than the total distance of travel of the damperstroke 1731. Further, if the pins emanating from one face 1788 werepermitted to enter into corresponding recesses 1734 in the other endworking surface, then the stroke distance permissible 1731 would befurther increased while reducing the overall length of the damper 1739.This new arrangement thus provides for a greater stoke.

The above description is meant to be exemplary only, and one skilled inthe art will recognize that changes may be made to the embodimentsdescribed without departing from the scope of the invention disclosed.It is understood that the features of any given one of the variousdescribed embodiments could be interchangeably integrated to the otherdescribed embodiments. That has the features described in connectionwith a given embodiment could be used in combination with the featuresof any other disclosed embodiments. Modifications which fall within thescope of the present invention will be apparent to those skilled in theart, in light of a review of this disclosure, and such modifications areintended to fall within the appended claims.

What is claimed is:
 1. A compensating damper comprising opposed workingend faces, a hermetically sealed chamber between the working end faces,a plurality of viscous fluid films separated by a set of plates disposedin the chamber between the working end faces, characterized in that eachviscous fluid film belongs to one of at least two different filmthickness zones disposed across the set of plates, each of the differentfilm thickness zones providing a different resistance response whenacted upon by an outside force exerted on at least one of said opposedworking end faces.
 2. A compensating damper comprising a set of platesdistributed along an axis and received in a chamber containing a workingfluid, each plate having a working face generally normal to said axis,said working face having an effective surface area, each plate at restbeing axially spaced from an adjacent plate by an inter-plate gap filledby the working fluid, each individual plate forming a piston for workingon the volume of the working fluid between it and the next plate, theplates being axially movable towards each other in response to anaxially compressive load to cause at least a portion of the workingfluid to escape from between the plates, wherein the chamber has opposedend working faces generally normal to the axis, the set of plates beingdisposed between said working end faces, the compensating dampercomprising multiple internal guide pins each extending axially from oneof the opposed working end faces towards the other of the opposedworking end faces and engaging at rest only a portion of the platestack.
 3. A compensating damper comprising an arrangement of platescontained in a chamber filled with a viscous fluid, the arrangement ofplates comprising an array of conical plates nested into one anotherwith a film of viscous fluid between adjacent plates, the conical shapeof the plates providing dampening in more than one geometric plane atonce.
 4. The compensating damper defined in claim 1, wherein multipleinternal guide pins each extend axially from only one of the opposedworking end faces towards the other of the opposed working end faces forengagement at rest with only a portion of the plates.
 5. Thecompensating damper defined in claim 2, wherein the internal guide pinsform a hole-circle about a center of the plates.
 6. The compensatingdamper defined in claim 2 wherein recesses are defined in each of theworking end faces for receiving respective distal ends of the internalguide pins extending from the other one of the opposed working endfaces.
 7. The compensating damper defined in claim 2 wherein for each ofsaid working end faces, the length of engagement of the associatedinternal guide pins into the set of plates at rest is less than a totaldistance of travel of a stroke of the damper.
 8. The compensating damperdefined in claim 2, wherein the internal guide pins extending from afirst one of said working end faces are offset relative to the internalguide pins extending from a second one of said working end faces.
 9. Thecompensating damper defined in claim 1, wherein the working end facesand the plates have a nested cone-shaped configuration.
 10. Thecompensating damper defined in claim 1, wherein the set of platescomprises a series of alternately stacked wavy and flat plates.
 11. Agun recoil pad comprising a compensating damper as defined in claim 1,the plates being held inside a mesh bag disposed inside the chamber, thechamber being at least partly formed by a hermetically sealedelastomeric boot adapted to be mounted to a butt stock of a gun, theboot being filled with the viscous fluid and pressurized, the internalpressure acting to cause tension in the boot.
 12. The gun recoil paddefined in claim 11, wherein the boot is closed at one end thereofagainst the butt stock of the gun by at least one plate clamping theelastomeric boot.
 13. The compensating damper defined in claim 3,wherein the plates are positioned in a cup shaped receiver and are actedupon by a cone shaped plunger sealed to the cup shaped receiver with adiaphragm shaped membrane.
 14. The compensating damper defined in claim13, further comprising externally adjustable springs.
 15. Thecompensating damper defined in claim 14, wherein jacking screws areprovided for adjusting the tension of the externally adjustable springs.16. A compensating damper energy dissipating link, comprising a sealedcanister holding a stack of fluid filled plates and with an externaltubular structural wall providing sufficient structural strength toallow the canister to act as a solid mounting link, a pair of workingfaces between which the stack of fluid filled plates is held, a joint ata first end of the canister to permit mounting of the link and a rodtype arrangement projecting from a second end of the canister, a weakpoint between the rod type arrangement and the second end to cause astress concentration point to fracture when a force exceeding the normaloperation is encountered, thereby allowing the rod to be run into thecanister and providing access to a dampening action.
 17. A vehiclehaving first and second frame members normally held in a fixedrelationship by at least one compensating damper energy dissipating linkdefined in claim 16 up until rupturing of the weak point.
 18. Acompensating damper energy dissipating link as defined in claim 16,wherein the canister is partly filled with an inert gas to provide acompressible internal volume within the canister.